Convection recirculating fryer for cooking foods

ABSTRACT

A convection recirculating food product fryer with a fry tank with and inlet tube connected to a heat exchanger and an outlet connected to a magnetic pump with an outlet tube to the heat exchanger, the pump having a driving magnet assembly housing an impeller and a driven magnet, with a ceramic shaft extending through the impeller about which the impeller rotates when pumping oil; an electric motor magnetically coupled to the magnetic pump; a burner to heat the oil in the heat exchanger; a controller to control the ignition and running of the burner.

TECHNICAL FIELD

The present invention is generally related to a convection fryingapparatus for cooking foods within a recirculating bath of cookingliquid.

BACKGROUND OF THE INVENTION

Although there are many ways to prepare food for consumption, one commonmethod of preparing foods is to cook the food by frying. Additionally,one method of frying food is to “deep fry” the food by placing theuncooked food in a quantity of cooking liquid. In most deep fryingsituations, the cooking liquid typically comprises a cooking oil, suchas vegetable oil or animal fat. The food product is immersed in thecooking oil. The cooking oil is typically at a high temperature, such asabove 350 degrees Fahrenheit.

Devices for deep frying are common in commercial food preparationenvironments. They are also becoming increasingly common in the homeenvironment. Although a commercial frying apparatus and a home fryingapparatus may he constructed on different scales, these two types offryers have some of the same basic features.

The primary feature of a typical fryer, whether commercial orresidential, is a cooking tank housing the heated bath of cooking oil.The cooking tank is usually designed so that it may receive a metalbasket into the tank. Food is placed in the metal basket and loweredinto the cooking oil so that the food is at least partially submersed inthe oil.

A heating device is typically used to maintain the oil in the tank at asubstantially constant temperature. This heating device usuallycomprises a gas burner placed below the tank.

The typical fryers used in commercial and residential settings do notremove the oil from the tank during operation. The cooking oil simplyremains in the tank and the temperature of the oil is regulated byheating the oil while the oil remains in the tank. In contrast, arecirculating fryer removes oil from the tank, adjusts the heat energyin the oil, and then returns the oil to the tank.

There have been previous attempts to develop a commercial recirculatingfryer. However, these recirculating fryer designs have all suffered froma number of limitations. For example, some recirculating fryer designsexhibited problems with leaking seals in the pump. The pump seals becameworn with use and began to leak. Other designs, while not necessarilyhaving a problem with leaking seals, experienced failure of the pumpbearings. This was usually a result of the arrangement of the pump. Ingeneral, the prior recirculating fryers were far too expensive tomaintain in order to be feasible for commercial use.

Thus, a heretofore unaddressed need exists in the industry to develop aconvection recirculating fryer that is efficient, cost-effective, andhaving reasonable maintenance costs.

BRIEF DESCRIPTION OF THE DRAWINGS

Many aspects of the invention can be better understood with reference tothe following drawings. The components in the drawings are notnecessarily to scale, emphasis instead being placed upon clearlyillustrating the principles of the present invention. Moreover, in thedrawings, like reference numerals designate corresponding partsthroughout the several views.

FIG. 1 is a side view of the convection recirculating fryer.

FIG. 1A is section view of the gas injectors of the convectionrecirculating fryer of FIG. 1.

FIG. 2A is a top view of the convection recirculating fryer of FIG. 1

FIG. 2B is a front view of the convection recirculating fryer of FIG. 1

FIG. 3 is cut away view of the magnetic pump of the convectionrecirculating fryer of FIG. 1.

FIG. 4 is a cut away side view of a magnetic pump to be used in theconvection recirculating fryer of FIG. 1.

FIG. 5 is an exploded part view of a magnetic pump used in theconvection recirculating fryer of FIG. 1.

DETAILED DESCRIPTION

A convection recirculating fryer of one exemplary embodiment comprises,generally, a fryer housing forming a tank, and encasing a pump and aheat exchanger. Although all of these elements are not required by theinvention disclosed herein, these three elements are the basiccomponents of an exemplary embodiment of a convection recirculatingfryer.

PARTS LIST 10. Convection fryer 11. Free standing housing 13. Fry tank16. Oil inlet orifice 17. Oil outlet orifice 18. Filter screen 19.Bottom of tank 20. Oil dispersement pipe 21. Magnetic pump 22. Pumpinlet line 26. Motor 27. Motor casing 28. Motor shaft 29. Driving magnetassembly 31. Impeller housing 32. Driven magnet 34. Impeller 35. Pumphousing 46. Hot oil supply line 50. Blower 52. Fuel injector tube 54.Glow plug with flame sensor 56. A-D Fuel injectors 58. Gas Manifold 60.Perforated burner sleeve 62. Control 64. Ceramic pump shaft 66. Magnet67. Seal 68. Filter pump

An exemplary embodiment of a convection recirculating fryer 10 isdepicted in FIG. 1. FIG. 1 is not to scale and is merely presented toprovide a general understanding of the components of the convectionrecirculating fryer 10. The arrangement of the components of theconvection recirculating fryer 10, as discussed below, is only oneexemplary arrangement.

FIG. 1 depicts the convection recirculating fryer 10 having a housing11. The housing 11 of the fryer 10 can be comprised of a metal material.The housing 11 of the preferred embodiment 10 is a free-standing housing11. FIG. 2A is a top view of the convection recirculating fryer 10.Alternatively, the housing 11 of the convection recirculating fryer 10could comprise a smaller, counter-top model, such as for home use. Theprinciples of the invention described herein are not changed by scalingthe fryer 10 up or down in size.

The fryer 10 also has a fry tank 13. See FIG. 1. The fry tank 13 of thepreferred embodiment 10 is adapted to receive and hold cooking liquid(not depicted), such as cooking oil (e.g. animal fat, shortening,vegetable-oil, or the like). The tank 13 of the preferred embodiment 10has an open top, an oil inlet orifice 16 and an oil outlet orifice 17.Basically, the preferred tank 13 resembles a deep tub, orretangularly-cubic bucket.

The tank 13 is also preferably designed to receive a basket (notdepicted). The basket typically houses a food product to be cooked inthe cooking liquid. Other implementations of placing food to be cookedin the cooking liquid are, of course, possible. The present invention isnot limited to any particular method and apparatus for exposing foodproducts to a cooking liquid.

The tank 13 of the preferred convection recirculating fryer 10 may alsocomprise a filter apparatus 18, as depicted in FIG. 3. As depicted inFIG. 3, the filter apparatus is a screen 18 positioned along the bottom19 of the tank 13. This apparatus maybe of any appropriate type;however, the preferred filtering apparatus is an active filtering devicethat pulls cooking liquid into the apparatus 18, removes foreign matter,and then deposits the cooking liquid back into the main compartment ofthe tank 13. The preferred filtering apparatus 18 is comprised of aframe that supports the filter material, or “filter sock,” and a gearpump. The filter sock is placed over the frame; which has a pipeconnection at a bottom portion. The gear pump draws the cooking liquidfrom the tank 13, through the filter sock, through an oil dispersementpipe 20, a filter pump 68, and back into the tank 13. Contaminants inthe cooking liquid are deposited on the filter sock where they becomeimbedded and remain there.

The fryer 10 also employs a passive filter (not depicted) at the oiloutlet orifice 17 of the tank 13. The convection recirculating fryer 10includes a magnetic pump 21 that draws cooking liquid from the tank 13.For this reason, a passive filtering apparatus could include ascreen-type assembly releasably mounted in the cooking tank 13, andsubstantially covering the oil outlet orifice 17 of the cooking tank 13,for prohibiting larger foreign matter from entering into the magneticpump 21 and disturbing heat exchanger 41.

As noted above, the tank 13 has an oil outlet orifice 17. This orifice17 is preferably near a lower portion of the tank 13. This orifice 17 ofthe tank 13 is connected to pump inlet line 22. This inlet line 22 isdesigned to carry the cooking liquid to an inlet of the pump 21.

The magnetic pump 21 is depicted in FIG. 4. The magnetic pump 21comprises a motor 26 in a motor casing 27. A motor shaft 28 to be drivenby the motor 26 protrudes from the motor casing 27 and is attached to adriving magnet assembly 29 comprising a driving magnet. The drivingmagnet assembly 29 of the preferred embodiment is cylindrical in shape.A magnet such as the driving magnet 29 can be manufactured from aSamarium Cobalt material which will withstand the high temperature ofthe cooking oil.

Inside the cylindrical driving magnet assembly 29, with a plurality ofmagnets 66, is an impeller magnet housing, or casing 31. The impellermagnet housing 31 of the magnetic pump 21 is hermetically sealed so thatany fluid in the impeller magnet housing 31 will not escape to an areaexterior to the impeller magnet housing 31.

Inside the impeller magnet housing 31 is a driving magnet 32 and animpeller 34. As depicted, the driven magnet 32 and the impeller 34 maybe a single unit. In an alternative embodiment, the impeller 34 and thedriven magnet 32 may be separate elements connected by a shaft. As isunderstood by one with ordinary skill in the art, the impeller 34 is theactual device that moves fluid through the magnetic pump 21.

The impeller magnet housing 31 is preferably connected to a pump housing35. The pump housing 35, in combination with the impeller magnet housing31, encases the impeller 34. The pump housing 35 has a pump inlet 36 anda pump outlet 37. The cooking liquid is drawn from the tank 13, thoughthe pump inlet line 22, into pump inlet 36 and into the pump housing 35by the action of the impeller 34. The impeller 34 also, through itsmotion, ejects the cooking liquid from the pump housing 35 of themagnetic pump 21. The cooking liquid is ejected though the pump outlet37 and into pump outlet line 38.

It is essential that the shaft 64 of the pump about which the impeller34 turns be constructed of ceramic material to withstand the heat of theoil. A seal 67 prevents the leakage of oil from the pump.

The preferred motor 26 of the magnetic pump 21 has approximately 1.0horsepower and will perform at approximately 3450 revolutions perminute. Of course, the motor 26 may be sized differently depending onthe particular design of the convection reciprocating fryer 10. Onehaving ordinary skill in the art will readily be able to size the motor26 for a particular fryer.

FIG. 5 depicts an exploded part diagram of the magnetic pump to be usedwith the present preferred embodiment. FIG. 5 depicts that pump 21comprises a motor 26 and a housing 27, a driving magnet assembly 29, animpeller magnet housing 31, an impeller 34, with driven magnets 32 and apump housing 35. Of course, this is only one possible magnetic pump thatmay be used with the present invention.

As depicted in FIG. 2A, the magnetic pump 21 is preferably situatedvertically within the fryer housing 11 in order to minimize thepossibility of a steam lock in the pump, which would prevent thecirculation of the oil through the fryer. Although preferred in theexemplary embodiment 10, the pump is not required to be situatedvertically. Also, the pump outlet 37 of the pump housing 35 is connectedby the pump outlet line 38 to a heat exchanger 41.

The preferred heat exchanger 41 comprises a series of tubing (notdepicted) with a heat source near, or even within, the tubing. In thepreferred embodiment 10, the heat exchanger 41 comprises a cylindricalheat exchanger as is conventionally known in the art. The heat exchangerhas a heat exchanger exhaust 42. The heat exchanger exhaust 42 of theheat exchanger 41 is in fluid communication with the pump outlet 37 ofthe pump 21 via the pump outlet line 38.

The heating element of the heat exchanger 41 preferably comprises aburner positioned along the axis of the heat exchanger 41. The heatingelement could be electric or gas powered, for example. It is preferredthat the heating element comprise an LP or natural gas powered burner.The heating element, of course, could also be equipped with a blower 50in order to more evenly distribute heat throughout the heat exchanger41.

Gas can be distributed through a gas manifold 58 as shown in FIG. 1A toa number of fuel injectors 56A-D to a fuel injector tube 52. Severalfuel injectors are preferred for the even burning of the gas. It hasbeen found that four injectors are preferred. The gas is ignited by aglow plug with a flame sensor 54 to make sure the gas is turned off ifit does not ignite in a specified time. The flame extends from the fuelinjector tube 52 into the heat exchanger 41 through a perforated burnersleeve 60. The convection recirculating fryer 10 is controlled by acontroller 60.

The heat exchanger 41 is designed such that the cooking oil travelsthrough heat exchanger tubing within the heat exchanger 41. The internalheat exchanger tubing is configured to permit the passage of the cookingoil back and forth across the burner within the heat exchanger. Theinternal tubing also includes fins for facilitating the absorption ofheat from the burner.

The heated cooking oil is ejected from the heat exchanger 41 at the hotoil supply line 46. Preferably, the cooking oil is moved from the heatexchanger 41 at a constant predetermined temperature (which is usuallyaround 350 degrees Fahrenheit). A control system (not depicted) operatesin conjunction with a temperature sensor (not depicted) mounted on theoutside of the hot oil supply line 46 to ensure that the cooking oiloutlet from the heat exchanger 41 remains at the predeterminedtemperature. Obviously, if the temperate of the cooking oil drops belowthe target value, or range, the heating element is instructed by thecontrol system to emit more heat energy into the cooking oil.Conversely, if the temperature of the cooking oil increases above thetarget value, or range, the heating element is caused to emit less heatenergy.

The hot oil supply line 46 of the heat exchanger 41 is connected to theoil inlet orifice 16 of the tank 13. Thus, the cooking oil completes itsjourney from the tank 13, to the pump 21, to heat exchanger 41, end backto the tank 13. As noted above, the magnetic pump 21 of the fryer 10 isthe device that actually causes the cooking oil to flow from the tank13, to the pump 21, to heat exchanger 41, and back to the tank 13. Theappropriate rate of flow of the oil can be determined by one of ordinaryskill in the art and is not important to the present invention.

It should be emphasized that the above-described embodiments of thepresent invention, particularly, any “preferred” embodiments, are merelypossible examples of implementations, merely set forth for a clearunderstanding of the principles of the invention. Many variations andmodifications may be made to the above-described embodiment(s) of theinvention without departing substantially from the spirit and principlesof the invention. All such modifications and variations are intended tobe included herein within the scope of this disclosure.

1-19. (canceled)
 20. A convection recirculating fryer, comprising: a frytank for receiving a fluid; and a magnetic pump operatively connected tothe fry tank for pumping the fluid through the fry tank, the magneticpump comprising: (i) a cylindrical driving magnet assembly having acircumference, wherein the cylindrical driving magnet assembly includesa plurality of driving magnets positioned in equidistant arrangementaround the circumference of the cylindrical driving magnet assembly;(ii) an impeller magnet housing encasing at least one driven magnet,wherein the impeller magnet housing is concentric with and receivable bythe cylindrical driving magnet assembly; and (iii) an impeller thatrotates about a stationary ceramic shaft extending through the impellerwhen pumping the fluid, wherein the plurality of driving magnets and theat least one driven magnet comprise a magnetic material that maintainsmagnetic properties when exposed to the fluid at temperatures in excessof 350° F.
 21. The fryer of claim 20, wherein the plurality of drivingmagnets are separated by a plurality of axially-aligned voids positionedtherebetween around the circumference of the cylindrical driving magnetassembly.
 22. The fryer of claim 20, wherein the plurality of drivingmagnets are separated by a plurality of circumferential gaps ofpredetermined width along the circumference of the cylindrical drivingmagnet assembly.
 23. The fryer of claim 20, wherein the plurality ofdriving magnets form a plurality of diametrically opposite pairs aroundthe circumference of the cylindrical driving magnet assembly.
 24. Thefryer of claim 20, wherein each of the plurality of driving magnetscomprises an elongate member positioned axially along an inner surfaceof the cylindrical driving magnet assembly.
 25. The fryer of claim 20,wherein the plurality of driving magnets comprises eight drivingmagnets.
 26. The fryer of claim 20, further comprising a heat exchangerin fluid communication with the fry tank for heating the fluid as thefluid passes through the heat exchanger.
 27. The fryer of claim 26,further comprising a means for heating the fluid as the fluid passesthrough the heat exchanger.
 28. The fryer of claim 27, furthercomprising a controller for controlling the heating means.
 29. The fryerof claim 28, wherein the means for heating the fluid as the fluid passesthrough the heat exchanger is a gas burner with a blower, an injectortube, and a plurality of symmetrically positioned gas injectors toevenly distribute the flame along a burner sleeve of the gas burner. 30.The fryer of claim 26, wherein the magnetic pump comprises an inlet influid communication with the fry tank and an outlet in fluidcommunication with the heat exchanger.
 31. The fryer of claim 30,wherein the magnetic pump is positioned in a substantially verticalorientation such that the inlet is positioned above the impeller. 32.The fryer of claim 31, further comprising an electric motor mechanicallycoupled to the magnetic pump and operative to drive the impeller suchthat the fluid from the fry tank enters the inlet of the magnetic pump,is imparted with velocity by the impeller, is directed to the heatexchanger, is heated in the heat exchanger, and then is provided back tothe fry tank.
 33. The fryer of claim 32, further comprising a glow plugwith a flame sensor to ignite gas, an injector tube and a plurality ofinjectors to inject gas into the tube, and a perforated burner sleeve tobetter distribute the flame in the heat exchanger, wherein the fluid isdistributed through the heat exchanger by tubing included within theheat exchanger.
 34. The fryer of claim 32, wherein the magnetic pump islocated above the electric motor.
 35. The fryer of claim 20, furthercomprising a filter to remove foreign matter from the fluid.
 36. Thefryer of claim 35, wherein the filter is positioned within an interiorof the fry tank for collecting the foreign matter within the fry tank.37. The fryer of claim 35, further comprising a filter pump forcirculating the fluid through the filter.
 38. The fryer of claim 20,wherein the stationary ceramic shaft extending through the impeller isoriented in a substantially vertical orientation.
 39. The fryer of claim20, wherein the magnetic material is Samarium Cobalt.
 40. A fryerapparatus, comprising: a tank for receiving a fluid; and a magnetic pumpoperatively connected to the tank for pumping the fluid through thetank, the magnetic pump comprising: (i) a cylindrical driving magnetassembly having a circumference, wherein the cylindrical driving magnetassembly includes a plurality of driving magnets positioned in aspaced-apart manner around the circumference of the cylindrical drivingmagnet assembly; (ii) an impeller magnet housing encasing at least onedriven magnet, wherein the impeller magnet housing is concentric withand receivable by the cylindrical driving magnet assembly; and (iii) animpeller that rotates about a stationary ceramic shaft extending throughthe impeller when pumping the fluid, wherein the plurality of drivingmagnets and the at least one driven magnet comprise a magnetic materialthat maintains magnetic properties when exposed to the fluid attemperatures in excess of 350° F.
 41. A convection recirculating fryerapparatus, comprising: a magnetic pump for pumping fluid through theconvection recirculating fryer apparatus, the magnetic pump comprising:(i) a cylindrical driving magnet assembly having a circumference,wherein the cylindrical driving magnet assembly includes a plurality ofdriving magnets positioned in equidistant arrangement around thecircumference of the cylindrical driving magnet assembly; (ii) animpeller magnet housing encasing at least one driven magnet, wherein theimpeller magnet housing is concentric with and receivable by thecylindrical driving magnet assembly; and (iii) an impeller that rotatesabout a stationary ceramic shaft extending through the impeller whenpumping the fluid, wherein the plurality of driving magnets and the atleast one driven magnet comprise a magnetic material that maintainsmagnetic properties when exposed to the fluid at temperatures in excessof 350° F.